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Ch. 26 – Abrasive Machining and Finishing Operations

Ch. 26 – Abrasive Machining and Finishing Operations. Brenton Elisberg, Jacob Hunner, Michael Snider, Michael Anderson. Abrasive Machining and Finishing Operations.

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Ch. 26 – Abrasive Machining and Finishing Operations

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  1. Ch. 26 – Abrasive Machining and Finishing Operations Brenton Elisberg, Jacob Hunner, Michael Snider, Michael Anderson

  2. Abrasive Machining and Finishing Operations • There are many situations where the processes of manufacturing we’ve learned about cannot produce the required dimensional accuracy and/or surface finish. • Fine finishes on ball/roller bearings, pistons, valves, gears, cams, etc. • The best methods for producing such accuracy and finishes involve abrasive machining.

  3. Abrasives and Bonded Abrasives • An abrasive is a small, hard particle having sharp edges and an irregular shape. • Abrasives are capable of removing small amounts of material through a cutting process that produces tiny chips.

  4. Abrasives and Bonded Abrasives • Commonly used abrasives in abrasive machining are: • Conventional Abrasives • Aluminum Oxide • Silicon Carbide • Superabrasives • Cubic boron nitride • Diamond

  5. Friability • Characteristic of abrasives. • Defined as the ability of abrasive grains to fracture into smaller pieces, essential to maintaining sharpness of abrasive during use. • High friable abrasive grains fragment more under grinding forces, low friable abrasive grains fragment less.

  6. Abrasive Types • Abrasives commonly found in nature include: • Emery • Corundum • Quartz • Garnet • Diamond

  7. Abrasive Types • Synthetically created abrasives include: • Aluminum oxide (1893) • Seeded gel (1987) • Silicon carbide (1891) • Cubic-boron nitride (1970’s) • Synthetic diamond (1955)

  8. Abrasive Grain Size • Abrasives are usually much smaller than the cutting tools in manufacturing processes. • Size of abrasive grain measured by grit number. • Smaller grain size, the larger the grit number. • Ex: with sandpaper 10 is very coarse, 100 is fine, and 500 is very fine grain.

  9. Grinding Wheels • Large amounts can be removed when many grains act together. This is done by using bonded abrasives. • This is typically in the form of a grinding wheel. • The abrasive grains in a grinding wheel are held together by a bonding material.

  10. Bonding Abrasives • Bonding materials act as supporting posts or braces between grains. • Bonding abrasives are marked with letters and numbers indicating: • Type of abrasive • Grain size • Grade • Structure • Bond type

  11. Bond Types • Vitrified: a glass bond, most commonly used bonding material. • However, it is a brittle bond. • Resinoid: bond consiting of thermosetting resins, bond is an organic compound. • More flexible bond than vitrified, also more resistant to higher temps.

  12. Bond Types • Reinforced Wheels: bond consisting of one or more layers of fiberglass. • Prevents breakage rather than improving strength. • Rubber: flexible bond type, inexpensive. • Metal: different metals can be used for strength, ductility, etc. • Most inexpensive bond type.

  13. The Grinding Process • Grinding is a chip removal process that uses an individual abrasive grain as the cutting tool. • The differences between grinding and a single point cutting tool is: • The abrasive grains have irregular shapes and are spaced randomly along the periphery of the wheel. • The average rake angle of the grain is typically -60 degrees. Consequently, grinding chips undergo much larger plastic deformation than they do in other machining processes. • Not all grains are active on the wheel. • Surface speeds involving grinding are very fast.

  14. (a) (b)

  15. Grinding Forces • A knowledge of grinding forces is essential for: • Estimating power requirements. • Designing grinding machines and work-holding fixtures and devices. • Determining the deflections that the work-piece as well as the grinding machine may undergo. Deflections adversely affect dimensioning.

  16. Grinding Forces • Forces in grinding are usually smaller than those in machining operations because of the smaller dimensions involved. • Low grinding forces are recommended for dimensional accuracy.

  17. Problems with Grinding • Wear Flat • After some use, grains along the periphery of the wheel develop a wear flat. • Wear flats rub along the ground surface, creating friction, and making grinding very inefficient.

  18. Problems with Grinding • Sparks • Sparks produced from grinding are actually glowing hot chips. • Tempering • Excessive heat, often times from friction, can soften the work-piece. • Burning • Excessive heat may burn the surface being ground. Characterized as a bluish color on ground steel surfaces.

  19. Problems with Grinding • Heat Checking • High temps in grinding may cause cracks in the work-piece, usually perpendicular to the grinding surface.

  20. Grain Fracture • Abrasive grains are brittle, and their fracture characteristics are important. • Wear flat creates unwanted high temps. • Ideally, the grain should fracture at a moderate rate so as to create new sharp cutting edges continuously.

  21. Bond Fracture • The strength of the abrasive bond is very important! • If the bond is too strong, dull grains cannot dislodge to make way for new sharp grains. • Hard grade bonds are meant for soft materials. • If too weak, grains dislodge too easily and the wear of the wheel increases greatly. • Soft grade bonds are meant for hard materials.

  22. Grinding Ratio • G = (Volume of material removed)/ Volume of wheel wear) • The higher the ratio, the longer the wheel will last. • During grinding, the wheel may act “soft” or hard” regardless of wheel grade. • Ex: pencil acting hard on soft paper and soft on rough paper.

  23. Dressing, Truing, Shaping • “Dressing” a wheel is the process of: • Conditioning worn grains by producing sharp new edges. • Truing, which is producing a true circle on the wheel that has become out of round. • Grinding wheels can also be shaped to the form of the piece you are grinding. • These are important because they affect the grinding forces and surface finish.

  24. Grinding Operations and Machines • Surface Grinding • Cylindrical Grinding • Internal Grinding • Centerless Grinding • Creep-feed Grinding • Heavy Stock Removal by Grinding • Grinding fluids

  25. Grinding Operations and Machines • Surface Grinding - grinding of flat surfaces • Cylindrical Grinding – axially ground

  26. Grinding Operations and Machines • Internal Grinding - grinding the inside diameter of a part • Creep-feed Grinding – large rates of grinding for a close to finished piece

  27. Grinding Operations and Machines • Centerless Grinding – continuously ground cylindrical surfaces

  28. Grinding Operations and Machines • Heavy Stock Removal - economical process to remove large amount of material • Grinding Fluids • Prevent workpiece temperature rise • Improves surface finish and dimensional accuracy • Reduces wheel wear, loading, and power consumption

  29. Design Consideration for Grinding • Part design should include secure mounting into workholding devices. • Holes and keyways may cause vibration and chatter, reducing dimensional accuracy. • Cylindrically ground pieces should be balanced. Fillets and radii made as large as possible, or relieved by prior machining.

  30. Design Considerations for Grinding • Long pieces are given better support in centerless grinding, and only the largest diameter may be ground in through-feed grinding. • Avoid frequent wheel dressing by keeping the piece simple. • A relief should be include in small and blind holes needing internal grinding.

  31. Finishing Operations • Coated abrasives • Belt Grinding • Wire Brushing • Honing • Superfinishing • Lapping • Chemical-Mechanical Polishing • Electroplating

  32. Finishing Operations • Coated Abrasives – have a more pointed and open structure than grinding wheels • Belt Grinding – high rate of material removal with good surface finish

  33. Finishing Operations • Wire Brushing - produces a fine or controlled texture • Honing – improves surface after boring, drilling, or internal grinding

  34. Finishing Operations • Superfinishing – very light pressure in a different path to the piece • Lapping – abrasive or slurry wears the piece’s ridges down softly

  35. Finishing Operations • Chemical-mechanical Polishing – slurry of abrasive particles and a controlled chemical corrosive • Electropolishing – an unidirectional pattern by removing metal from the surface

  36. Deburring Operations • Manual Deburring • Mechanical Deburring • Vibratory and Barrel Finishing • Shot Blasting • Abrasive-Flow Machining • Thermal Energy Deburring • Robotic Deburring

  37. Deburring Operations • Vibratory and Barrel Finishing – abrasive pellets are tumbled or vibrated to deburr • Abrasive-flow Machining – a putty of abrasive grains is forced through a piece

  38. Deburring Operations • Thermal Energy Deburring – natural gas and oxygen are ignited to melt the burr • Robotic Deburring – uses a force-feedback program to control the rate and path of deburring

  39. Economics of Abrasive Machining and Finishing Operations • Creep-feed grinding is an economical alternative to other machining operations. • The use of abrasives and finishing operations achieve a higher dimensional accuracy than the solitary machining process. • Automation has reduced labor cost and production times. • The greater the surface-finish, the more operations involved, increases the product cost. • Abrasive processes and finishing processes are important to include in the design analysis for pieces requiring a surface finish and dimensional accuracy.

  40. Chapter 27 – Advanced Machining Processes

  41. Chapter 27 – Advanced Mechanical Processes • Advanced Machining Processes can be used when mechanical methods are not satisfactory, economical or possible due to: • High strength or hardness • Too brittle or too flexible • Complex shapes • Special finish and dimensional tolerance requirements • Temperature rise and residual stresses

  42. Advanced Mechanical Processes • These advanced methods began to be introduced in the 1940's. • Removes material by chemical dissolution, etching, melting, evaporation, and hydrodynamic action. • These requirements led to chemical, electrical, laser, and high-energy beams as energy sources for removing material from metallic or non-metallic workpieces.

  43. Chemical Machining • Chemical machining • Uses chemical dissolution to dissolve material from the workpiece. • Can be used on stones, most metals and some ceramics. • Oldest of the advanced machining processes.

  44. Chemical Machining • Chemical milling - shallow cavities are produced on plates, sheets, forgings, and extrusions, generally for the overall reduction of weight. • Can be used with depths of metal removal as large as 12 mm. • Masking is used to protect areas that are not meant to be attacked by the chemical.

  45. Chemical Machining • Chemical Blanking – similar to the blanking of sheet metals with the exception that the material is removed by chemical dissolution rather than by shearing. • Printed circuit boards. • Decorative panels. • Thin sheet-metal stampings. • Complex or small shapes.

  46. Chemical Machining • Surface Roughness and Tolerance table

  47. Chemical Machining • Photochemical blanking/machining • Modification of chemical milling. • Can be used on metals as thin as .0025 mm. • Applications • Fine screens. • Printed circuit boards. • Electric-motor laminations. • Flat springs. • Masks for color televisions.

  48. Chemical Machining • Chemical machining design considerations • No sharp corners, deep or narrow cavities, severe tapers, folded seam, or porous workpiece materials. • Undercuts may develop. • The bulk of the workpiece should be shaped by other processes prior to chemical machining.

  49. Electrochemical Machining • Electrochemical machining (ECM) • An electrolyte acts as a current carrier which washes metal ions away from the workpiece (anode) before they have a chance to plate on the tool (cathode). • The shaped tool is either solid or tubular. • Generally made of brass, copper, bronze or stainless steel. • The electrolyte is a highly conductive inorganic fluid.

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